PSO_SA算法在水下结构激励力源识别中的应用

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振动与冲击 ›› 2016, Vol. 35 ›› Issue (12) : 226-232.

论文

肖妍 1,2, 商德江 1,2

作者信息 +

Application of PSO_SA Algorithm in Underwater Structure Exciting Force Source Identification

Xiao Yan 1,2；Shang Dejiang 1,2

Author information +

文章历史 +

摘要

提出一种识别水下弹性结构内部激励力源的匹配场处理方法，建立基于辐射声场的广义拷贝场概念，并提出采用粒子群模拟退火融合搜索算法对最优力源强度进行匹配搜索。以水下自由声场中的单层圆柱壳体作为研究对象，对声压传递函数进行了数值计算，针对激励力源识别匹配场处理方法进行了数值仿真分析。在消声水池中进行了水下单层圆柱壳体结构振动与辐射声场测试，将测试结果与拷贝场进行匹配处理，搜索最优力源强度，并以该搜索结果进行了圆柱壳体辐射噪声预报。仿真结果与试验结果均表明，这种方法可以有效的针对结构内部的力源强度进行分析排序。同时，利用匹配识别的结果进行辐射噪声预报时，预报精度很高。

Abstract

An identification method by MFP is proposed for exciting force source inside the underwater structure, and a concept of generalized copy field based on the structural acoustic radiation field is established. The particle swarm optimization _ simulated annealing (PSO_GA) algorithm is adopted for searching the optimum force source strengths. A single cylindrical shell in underwater free field is selected as the investigated subject, and the sound radiation transfer function copy field is numerically calculated. The matched searching algorithm is simulated. The vibration and radiation sound pressures of the actual single cylindrical shell are measured in the anechoic tank. The measurement result and the numerical copy field are matching processed to search the optimum source strength. Both the simulation and the experiment results show that this method is effective for analyzing the source intensity. And more, the forecast accuracy is high when using the source matching identification results to predict the radiation sound pressures.

导出引用

肖妍 1,2, 商德江 1,2. PSO_SA算法在水下结构激励力源识别中的应用[J]. 振动与冲击, 2016, 35(12): 226-232

Xiao Yan 1,2；Shang Dejiang 1,2. Application of PSO_SA Algorithm in Underwater Structure Exciting Force Source Identification[J]. Journal of Vibration and Shock, 2016, 35(12): 226-232

参考文献

[1] Chakravorty P k．Identification of self noise sources in a ship[J]．Naval Engineers Journal, 1990, 102:67-69．
[2] 蒋国建，任克明，马杰等．噪声抵消法估计和抑制声呐部位主要自噪声[J]. 声学学报，1996,21(4):289-296．
Jing Guojian, Ren Kemin, Ma Jie, et.al. Estimation and rejecting the main self-noise of sonar-position by noise cancelling method[J]. ACTA Acustica, 1996,21(4): 289-296.
[3] 董建超，杨铁军，李新辉，代路．主分量分析在激励源识别中的应用研究．振动与冲击．2013, 32(24)：157-163．
DONG Jian-chao，YANG Tie-jun，LI Xin-hui，DAI Lu. Applications of principal component analysis in excitation source identification[J]. Journal of vibration and shock, 2013, 32(24)：157-163．
[4] 时胜国，杨德森. 水下声强测量分析系统及其在近场测量中的应用[J]. 测试技术学报，2002，16：475-480．
Shi Shengguo, Yang Desen. An Underwater Sound Intensity Measurement System and its Application to Its Radiation Noise Measurement of Underwater Structure in the Near-Field[J]. Journal of Test and Measurement Technology. 2002,16:475-480.
[5] 陈梦英，商德江，李琪，刘永伟．运动声源的边界元声全息识别方法研究[J]. 声学学报，2011，31(5): 489-495．
Chen Mengying, Shang Dejiang, Li Qi, Liu Yongwei. Nearfield acoustic holography based on inverse boundary element method for moving sound source identification[J]. ACTA Acustica, 2011，31(5): 489-495．
[6] Arthur B. Baggeroer, W. A. Kuperman. An Overview of Matched Field Methods in Ocean Acoustics[C]. IEEE Journal of Oceanic Enigeeing. 1993,18:425-427.
[7] Tolstoy A, Horoshenkov K V, Bin Ali M T. Detecting pipe changes via acoustic matched field processing[J]. Applied Acoustics, 2009, 70: 695-702.
[8] 董姝敏，刘洪波，赵博，梁国龙.匹配场声源定位的并行计算方法研究[J]. 计算机应用研究，2012，29（2）：514-517.
Dong Shumin, Liu Hongbo Zhao bo, Liang Guolong. Study on method of parallel computing in match field localization[J]. Application Research of Computers, 2012,29(2):514-517.
[9]　Xiao Yan, Shang De-jiang. Identification Method for Exciting Force Source Inside Underwater Structure Based on PSO_GA. Journal of Ship Mechanics. 2015, 19(3): 311-321.
[10] F-J Fahy. Sound and structural vibration: Radiation, transmission and response[M]. Amsterdam Boston Elsevier Academin, 2007.
[11] 王振树, 李林川, 李波. 基于粒子群与模拟退火相结合的无功优化算法[J]. 山东大学学报(工学版)，2008，38(6)：15-20.
Wang Zhenshu, Li Linchuan, Libo. Reactive power optimization based on particle swarm optimization and simulated annealing cooperative algorithm[J]. Journal of Shandong University(Engineering Science). 2008，38(6)：15-20.
[12] 王华秋, 曹长修. 基于模拟退火的并行粒子群优化研究[J].控制与决策，2005，20(5)：500-504.
Wang Huaqiu, Cao Changxiu. Parallel particle swarm optimization based on simulated annealing[J]. Control and Decision, 2005,20(5):500-504
[13] 吴绍维, 向阳, 夏雪宝. 基于无单元声波叠加的自辐射近似解析表达研究．振动与冲击．2014, 33(7)：79-85．
WU Shao-wei, XIANG Yang, XIA Xue-bao. Approximate analytical expressions of self-radiation terms inclading acoustic pressure and velocity based on element free acoustic wave superposition[J]. Journal of vibration and shock, 2014, 33(7)：79-85．